Li_(1.3)Al_(0.3)Ti_(1.7)(PO_(4))_(3)(LATP),of much interest owing to its high ionic conductivity,superior air stability,and low cost,has been regarded as one of the most promising solid-state electrolytes for next-gen...Li_(1.3)Al_(0.3)Ti_(1.7)(PO_(4))_(3)(LATP),of much interest owing to its high ionic conductivity,superior air stability,and low cost,has been regarded as one of the most promising solid-state electrolytes for next-generation solid-state lithium batteries(SSLBs).Unfortunately,the commercialization of SSLBs is still impeded by severe interfacial issues,such as high interfacial impedance and poor chemical stability.Herein,we proposed a simple and convenient in-situ approach to constructing a tight and robust interface between the Li anode and LATP electrolyte via a SnO_(2)gradient buffer layer.It is firmly attached to the surface of LATP pellets due to the volume expansion of SnO_(2)when in-situ reacting with Li metal,and thus effectively alleviates the physical contact loosening during cycling,as confirmed by the mitigated impedance rising.Meanwhile,the as-formed SnO_(2)/Sn/LixSn gradient buffer layer with low electronic conductivity successfully protects the LATP electrolyte surface from erosion by the Li metal anode.Additionally,the LixSn alloy formed at the Li surface can effectively regulate uniform lithium deposition and suppress Li dendrite growth.Therefore,this work paves a new way to simultaneously address the chemical instability and poor physical contact of LATP with Li metal in developing low-cost and highly stable SSLBs.展开更多
Cycle stability and thermal safety are critical to the commercialization of nickel-rich layered materials,yet whether there is a potential correlation between these two factors is still controversial. Herein, the rela...Cycle stability and thermal safety are critical to the commercialization of nickel-rich layered materials,yet whether there is a potential correlation between these two factors is still controversial. Herein, the relationship between the cycle stability and thermal stability of nickel-rich cathode materials have been systematically studied through five different calcination temperatures of Li[NiCoMn]O(NCM83) cathode materials. The research results confirm that the cycle stability and thermal safety of nickel-rich cathode materials do not necessarily show a positive correlation. Actually, with the calcination temperature elevated, the thermal stability of the NCM83 is enhanced, while the cycle stability is degraded. This opposite correlation is not commonly reported in previous literatures. In this work, systematical characterizations demonstrate that under the experimental conditions, the capacity retention of NCM83 is mainly determined by the Li/Ni cation disorder and H2-H3 irreversible phase transition,which is optimal at lower calcination temperature. Meanwhile, the thermal stability is mainly impacted by thermal expansion characteristics and interfacial stability of cathode material, and it is dramatically improved by the mechanical strength of the secondary particles reinforced at high calcinated temperature. This study provides some new insights on understanding and designing of the high-energy cathode materials with long cycle-life and superior safety.展开更多
Objective: To study the effects of -zinc sulfate combined with yiqiyangyinghuoxue therapy on related factors in patients with type 2 diabetes peripheral neuropathy. Methods: A total of 90 patients with type 2 diabetes...Objective: To study the effects of -zinc sulfate combined with yiqiyangyinghuoxue therapy on related factors in patients with type 2 diabetes peripheral neuropathy. Methods: A total of 90 patients with type 2 diabetes peripheral neuropathy in our hospital from September 2015 to September 2018 were enrolled in this study. The subjects were divided into the control group (n=45) and the treatment group (n=45) randomly. The control group were treated with -zinc sulfate, the treatment group were treated with -zinc sulfate combined with yiqiyangyinghuoxue therapy, the two groups were treated for 3 months. The serum NSE, UA, Hcy, hs-CRP, BDNF, HMGB1, CysC, TGF-β1, 25-(OH)D3, ESM-1, NO and plasma ET, TNF of the two groups before and after treatment were compared. Results: There were no significantly differences of the serum NSE, UA, Hcy, hs-CRP, BDNF, HMGB1, CysC, TGF-β1, 25-(OH)D3, ESM-1, NO and plasma ET, TNF of the two groups before treatment. After treatment, the serum NSE, UA, Hcy, hs-CRP, HMGB1, CysC, TGF-β1, ESM-1 and plasma ET, TNF of the two groups were significantly lower than before treatment, the serum BDNF, 25-(OH)D3, NO of the two groups were significantly higher than before treatment, and that of the treatment group after treatment were significantly better than the control group. Conclusion: α-zinc sulfate combined with yiqiyangyinghuoxue therapy on patients with type 2 diabetes peripheral neuropathy has a good efficacy, can improve the neuropathy and vascular endothelial damage, improve related factors, and it was worthy clinical application.展开更多
基金financially supported by the China Postdoctoral Science Foundation(2021M700396)the National Natural Science Foundation of China(52102206)the research grants from the National Research Foundation(2022K1A3A1A20014496 and 2022R1F1A1074707)funded by the government of the Republic of Korea。
文摘Li_(1.3)Al_(0.3)Ti_(1.7)(PO_(4))_(3)(LATP),of much interest owing to its high ionic conductivity,superior air stability,and low cost,has been regarded as one of the most promising solid-state electrolytes for next-generation solid-state lithium batteries(SSLBs).Unfortunately,the commercialization of SSLBs is still impeded by severe interfacial issues,such as high interfacial impedance and poor chemical stability.Herein,we proposed a simple and convenient in-situ approach to constructing a tight and robust interface between the Li anode and LATP electrolyte via a SnO_(2)gradient buffer layer.It is firmly attached to the surface of LATP pellets due to the volume expansion of SnO_(2)when in-situ reacting with Li metal,and thus effectively alleviates the physical contact loosening during cycling,as confirmed by the mitigated impedance rising.Meanwhile,the as-formed SnO_(2)/Sn/LixSn gradient buffer layer with low electronic conductivity successfully protects the LATP electrolyte surface from erosion by the Li metal anode.Additionally,the LixSn alloy formed at the Li surface can effectively regulate uniform lithium deposition and suppress Li dendrite growth.Therefore,this work paves a new way to simultaneously address the chemical instability and poor physical contact of LATP with Li metal in developing low-cost and highly stable SSLBs.
基金financially supported by the China Postdoctoral Science Foundation(2021M700396)the National Natural Science Foundation of China(52102206)the National Research Foundation of Republic of Korea(2021K2A9A2A06044652)。
文摘Cycle stability and thermal safety are critical to the commercialization of nickel-rich layered materials,yet whether there is a potential correlation between these two factors is still controversial. Herein, the relationship between the cycle stability and thermal stability of nickel-rich cathode materials have been systematically studied through five different calcination temperatures of Li[NiCoMn]O(NCM83) cathode materials. The research results confirm that the cycle stability and thermal safety of nickel-rich cathode materials do not necessarily show a positive correlation. Actually, with the calcination temperature elevated, the thermal stability of the NCM83 is enhanced, while the cycle stability is degraded. This opposite correlation is not commonly reported in previous literatures. In this work, systematical characterizations demonstrate that under the experimental conditions, the capacity retention of NCM83 is mainly determined by the Li/Ni cation disorder and H2-H3 irreversible phase transition,which is optimal at lower calcination temperature. Meanwhile, the thermal stability is mainly impacted by thermal expansion characteristics and interfacial stability of cathode material, and it is dramatically improved by the mechanical strength of the secondary particles reinforced at high calcinated temperature. This study provides some new insights on understanding and designing of the high-energy cathode materials with long cycle-life and superior safety.
文摘Objective: To study the effects of -zinc sulfate combined with yiqiyangyinghuoxue therapy on related factors in patients with type 2 diabetes peripheral neuropathy. Methods: A total of 90 patients with type 2 diabetes peripheral neuropathy in our hospital from September 2015 to September 2018 were enrolled in this study. The subjects were divided into the control group (n=45) and the treatment group (n=45) randomly. The control group were treated with -zinc sulfate, the treatment group were treated with -zinc sulfate combined with yiqiyangyinghuoxue therapy, the two groups were treated for 3 months. The serum NSE, UA, Hcy, hs-CRP, BDNF, HMGB1, CysC, TGF-β1, 25-(OH)D3, ESM-1, NO and plasma ET, TNF of the two groups before and after treatment were compared. Results: There were no significantly differences of the serum NSE, UA, Hcy, hs-CRP, BDNF, HMGB1, CysC, TGF-β1, 25-(OH)D3, ESM-1, NO and plasma ET, TNF of the two groups before treatment. After treatment, the serum NSE, UA, Hcy, hs-CRP, HMGB1, CysC, TGF-β1, ESM-1 and plasma ET, TNF of the two groups were significantly lower than before treatment, the serum BDNF, 25-(OH)D3, NO of the two groups were significantly higher than before treatment, and that of the treatment group after treatment were significantly better than the control group. Conclusion: α-zinc sulfate combined with yiqiyangyinghuoxue therapy on patients with type 2 diabetes peripheral neuropathy has a good efficacy, can improve the neuropathy and vascular endothelial damage, improve related factors, and it was worthy clinical application.